DE3824563C2 - - Google Patents

Description

The invention relates to a method for lifting and Support heavy, large loads, especially from rail-bound wagons on several predetermined Working heights on supports and a device for Execution of the procedure.

In the construction, maintenance and cleaning of railway wagons have to do this in order to do the various jobs Operating personnel to an optimal working height ensure arranged at different working heights will.

To make this possible, they are fixed or movable Screw jacks known. For lifting a wagon onto one any height is four such screw jacks required, whose drives must be synchronized, to ensure an even lifting or lowering. Such screw jacks are in their case Movability extremely bulky and in the case of it Tied to location they require additional extensive construction measures. In addition, working under load a special permit for such screw jacks required, which must be renewed annually and extensive Inspection measures require longer downtimes condition. Overall, working with such Screw jack systems extremely cost-intensive.

In the case of repetitive, similar operations, it is  sufficient if the wagons on two or three, if necessary, four working heights can also be set. It are therefore known lifting devices, for. B. Lifting platforms in single or multiple scissor-type construction with which the wagons are lifted and characterizing it to the respective working height Supports are discontinued. In the known scissor lifts the scissors will be attached to one of them Hydraulic cylinder actuated. To a reasonably priced one Point of engagement to ensure power transmission these lifts have a minimum height when folded Condition that is often the minimum working height exceeds. Also, according to the number of required working heights a corresponding number of Pairs of supports are required which are substantial Require space and transport problems with it bring.

DE-A 30 25 017 describes a method with the features of the preamble of claim 1 and a device known with the features of the preamble of claim 3.

In these methods and in the known Device guides are necessary, which are mandatory make stationary arrangement necessary. Through the Tours also have free access to the load limited.

From DE-A 35 37 640 it is of a lever system for Aircraft known in principle, a load platform over a To couple scissors arrangement with a mobile base plate and lift hydraulically.

The object of the invention is a method and Device for lifting and supporting heavy, large-scale  Specify loads that allow simple and Fast way even large loads on any to raise the specified working heights and to the working heights to distinguish characteristic supports that are low Require space and still secure support allow and are easy to use.

This task is accomplished by a process with the characteristics of Claim 1 and by a device with the features of claim 3 solved.

Advantageous configurations of the device are See subclaims.

The invention is illustrated below using an exemplary embodiment  the establishment with advantages and with reference explained in more detail on drawings. It shows:

A lifting device embodied Fig. 1 in schematic representation,

Fig. 2 is an end plan view of a support exported from three supporting structures,

Fig. 3 shows the same in side view.

The executed lifting device ( FIG. 1) has a base plate 1 and a load platform 2 . Arranged between the base plate 1 and the load platform 2 are two hydraulically actuable telescopic cylinders 3 and a scissor arrangement 4 which guarantees the parallelism of the base plate 1 to the load platform 2 during the lifting and lowering movements. Air cushions (not visible in FIG. 1 ) are preferably arranged under the base plate 1 , which enable the lifting device to be moved in any direction. Known devices for the hydraulic or pneumatic drive of the air cushions or the telescopic cylinder 3 , which contain known pneumatic and hydraulic and control units, are located on the base plate 1 under cover housings 5 . Swing-out load arms 6 are provided on the load platform 2 , which can optionally also be arranged to be height-adjustable or extendable.

The fact that the lifting drive does not act on the scissor assembly but directly on the load platform 2 , the scissors can be closed completely, so that they only require a small height when folded, so that the entire lifting device can be built extremely flat, so that only low clearance heights are required. The air cushions enable it to be moved in any direction and thus great maneuverability, which can also be carried out by hand without additional machines. The lifting device has connections (not shown) for a control device and to a compressed air source.

The supports shown ( FIGS. 2 and 3) consist of three support structures 7 , 8 and 9 , which can be stacked one above the other, their focal points lying in the plane of symmetry XX perpendicular to their longitudinal extent. Each support frame 7 , 8 , 9 consists of steel profiles and has a downwardly open U-shaped portal 10 , the cross-beam 11 is attached at both ends to side supports 12 such that the cross-beam 11 of each support frame 7 , 8 , 9 parallel and in the same distance from the floor surface 13 is arranged if each of the support structures 7 , 8 , 9 is arranged on the floor surface 13 . The side supports 12 can be designed as a closed rectangle as with the support frame 7 with or without stand extensions 14 , so that two standing surfaces are available. However, they can also be designed as U-shaped side supports open at the bottom, as in the support structures 8 or 9 , so that the support structures 8 and 9 are supported on four support feet 15 . The support feet 15 may have extensions extending beyond the crossbar 11 , e.g. B. projections 16 (see the support structure 8 ) or extension supports, which are connected by an additional crossbar 18 (see the support structure 9 ). The crossbar 11 and the additional crossbar 18 can be connected by support members 19 to stiffen the support frame 9 .

Each of the support structures 7 , 8 , 9 has support surfaces for the support structure 8 or 7 to be arranged on it. These support surfaces can be designed as projecting outer angles 20 (on the support frame 9 ) which center the support feet 15 of the support frame 8 and secure them against displacement in any direction in the horizontal plane. The stand extensions 14 of the side supports 12 of the support frame 7 are designed so that they can go straight between the extension projections 16 of the support feet 15 of the support frame 8 . As a result, a displacement between the extension projections 16 is excluded. In order to also prevent a movement transversely thereto, for example wedge-shaped or conical projections 21 can be provided on the crossbar 11 of the support frame 8 , which corresponding recesses in the standing surface of the support frame 7 correspond.

In order to increase the mobility, in particular of the larger dimensions and thus also higher weights, of support frames 8 and 9 , preferably spring-loaded, freely rotatable casters 22 can be provided on their support feet 15 . The springs, not shown, are designed so that the castors 22 protrude from the support legs 15 in the unloaded state of the individual support frames 8 , 9 and thus allow any travel. In the loaded state, be it by a further support structure ( 7 , 8 ) or by the load to be carried, the casters 22 are drawn into the support feet 15 so that their larger footprint compared to the support of the casters 22 comes into effect.

Each of the support frames 7 , 8 , 9 has at least one part 23 or 24 of a locking unit 25 arranged on each side support 12 . The locking unit 25 can have a part 23 in the form of a pivotable bolt provided with a screw thread and a nut arranged thereon and a part 24 arranged on the other of the support structures to be locked together in the form of an abutment with an opening into which the screw bolt can be inserted and on which the nut of the bolt can be supported by screwing for mutual locking. The locking unit 25 can have any known and suitable construction, with which two supporting structures can be locked against each other and then released from each other again.

The method according to the invention is carried out with the device as follows. A railway wagon to be arranged in different working heights is z. B. deposited by means of a crane on the intended support surfaces of the railway wagon on two lifting devices set up parallel to one another. The two lifting devices are connected to a compressed air source and a control unit and the lifting cushions of the lifting devices are pressurized with compressed air, so that the lifting devices can be moved with their load into any desired position by hand or by a small drive device. At the desired point, the air cushions are switched off and the lifting devices are supported with their contact surfaces on the floor surface 13 . Then the pneumatic telescopic cylinders 3 are extended evenly with both lifting devices and the wagon is raised by a synchronous control, optionally with a known monitoring and automatic compensation control. The stroke continues until the support level of the scaffolding 7 is exceeded. Then a support frame 7 is assigned to each lifting device and aligned with the lifting device. This alignment can be done in that the inner spacing of the side supports 12 is adapted to the outer spacing of the base plate 1 practically without play and the height of the portal allows the support frame 7 to abut partially over the base plate 1 of the lifting device, possibly against stops (not shown) , can be arranged. As a result, the support device 7 and the lifting device are aligned with one another in a simple manner. The load is then lowered onto the support structures 7 and the lifting devices can be removed for other lifting operations. In the event that a different working height is initially desired, the load arms 6 are pivoted out on the load platform 2 , for example under the crossbar 11 of the supporting frame 7 . The load arms 6 can, for example, also be arranged so as to be extendable and can be pivoted or inserted into corresponding openings on the supporting structure, it being important to ensure that the supporting structure can be raised and lowered without fluctuating. After it has been ensured that the load arms 6 are coupled to the scaffolding 7 or are coupled when lifting, the drive of the telescopic cylinder 3 is switched on and these are extended synchronously to a level sufficient for the scaffolding 8 below the raised scaffolding 7 to arrange. Then the telescopic cylinders 3 are slowly lowered synchronously, the wedge-shaped or conical projections 21 of the support frame 8 coming into contact with the corresponding recesses of the support frame 7 , as a result of which it is aligned precisely since the support frame 8 is not yet loaded and thus still free is movable. When the lifting cylinders 3 are lowered further, the support frame 7 is then supported on the support frame 8 and when the telescopic cylinders 3 are lowered further, the load is supported on the support frames 7 and 8 arranged one above the other. In this operation, the lifting devices can either be removed for other work or the third working height is desired. For this purpose, the scaffolding 7 is first firmly locked against the scaffolding 8 by means of the locking unit 25 . Then the drive of the telescopic cylinders 3 is switched on and these are lifted synchronously and evenly, the second support frame 8 also being raised simultaneously by the coupling of the support frame 7 via the load arms 6 to the load platform 2 of the lifting device and the coupling of the second support frame 8 to the support frame 7 will. The lifting movement is continued as long as pre-centered to the third support frame 9 by the two coupled support structures 7 and 8 can be retracted. The telescopic cylinders 3 are then lowered, the support feet 15 of the support frame 8 sliding in and centered against the displacement in the arrangement plane by the angular projections on the support frame 9 . Due to the movability of the support frame 9 , a possible correction of the mutual arrangement is easily possible beforehand. Then the telescopic cylinders 3 are retracted further and the load is supported on the support frames 7 , 8 , 9 arranged one above the other. It is advisable to lock all support structures 7 , 8 , 9 with one another by the locking units 25 while working on the supports. It goes without saying that when the lifting devices are removed for further work, the load arms 6 of the load platform 2 are then pivoted in or pulled in, so that the otherwise coupled support frame 7 is released.

The working height is reduced in such a way that the lifting devices are retracted under the portal 10 of the support frame 9 , after which the telescopic cylinders 3 are extended so far that the load arms 6 of the load platform 2 can be coupled to the uppermost support frame 7 . Then the locking unit 25 between the support frames 8 and 9 is released , after which the two coupled support frames 7 and 8 are raised by means of the load arms 6 in a further stroke by means of the telescopic cylinders 3 . As a result, the support structure 8 is free and can be removed from the load area due to the casters 22 being pushed out by spring force. Then the telescopic cylinders 3 are lowered further and the load and the support structures 7 and 8 are lowered so far that the locking unit 25 between the support structures 7 and 8 can be released. This is followed by a slight lifting by means of the telescopic cylinder 3 to such an extent that the supporting frame 8 can now be moved freely and can be removed. Then the lowering takes place by means of the telescopic cylinder 3 to such an extent that the load is supported on the support frame 7 . The coupling of the load arms 6 of the load platform 2 to the support structure 7 is released and the load is either supported on the support structures 7 or these can be removed and removed, if necessary, by extending the telescopic cylinders 3 again .

It is possible by appropriate design of the load capacity the air cushion the car with any number differently arranged support structures Feed workstations. Are in the embodiment the supports are made in three parts for three working levels, if only two or more working levels are required, the Supports are made in two or more parts.

Claims (8)

1.Procedure for lifting and supporting heavy, large-scale loads, in particular of rail-bound wagons at several predetermined working heights on two supports, the load being aligned on two separate lifting devices on a load platform and synchronously in the immediate vicinity and centered, removable and axially stackable on the lifting devices Outriggers can be arranged, characterized in that movable lifting devices and supporting frames are used as supports, the supporting frames defining working heights individually and in combination with one another and that the load is raised by the lifting devices to a height slightly exceeding a first lower working height, after which the first working height Corresponding scaffolds are aligned on the floor surface and the load is lowered onto the scaffolding and that the lifting devices raise the load slightly to raise the load to a second higher working level ben and then the scaffolding are coupled to the load platform and so raised during the further load stroke that a second scaffolding centered on the floor surface under each first scaffolding, which together with the first scaffolding represents a second working height, can be arranged, after which the first scaffolding to the second and time-shifted the load is placed on both scaffolds, after which, if necessary, both support scaffolds are firmly connected to each other for lifting to a third higher working height and when the load is lifted time-shifted together so far that a third one together with the first two third working height-defining scaffolding can be arranged centered on the floor surface, to which the first two supporting scaffolds and then to all three the load is placed and that the load is lowered to a lower working height and then shifted in time with the load platform rm coupled first scaffolding and, if necessary, the second supporting scaffold still connected, so far that the free lower supporting scaffold can be removed, after which the corresponding lowering and supporting of the first supporting scaffold coupled to the load platform and, if appropriate, the second supporting scaffold still connected to it and then the load done at a low working height. 2. The method according to claim 1, characterized in that the third is firmly connected to the second scaffolding becomes. 3. Device for performing the method according to claim 2 with synchronously operable on a base plate ( 1 ) arranged telescopic cylinder ( 3 ) having lifting devices and with stackable supports, characterized in that the supports are support structures ( 7, 8, 9 ) and locking units ( 23, 24, 25 ) for mutually rigid locking and that the telescopic cylinders ( 3 ) are connected to a load platform ( 2 ), the base plate ( 1 ) being coupled to the load platform ( 2 ) via a scissor arrangement ( 4 ) and that Load platform ( 2 ) has extendable load arms ( 6 ) which can at least be detachably coupled to a support frame ( 7 ). 4. Device according to claim 3, characterized in that the lifting devices are arranged on air cushions. 5. Device according to claim 3 or 4, characterized in that each support structure ( 7, 8, 9 ) is constructed from steel profiles such that it has a downwardly open U-shaped portal ( 10 ) in the longitudinal direction. 6. Device according to claim 5, characterized in that the portal ( 10 ) has dimensions such that it can be passed under at least partially and at least laterally almost without play from an unloaded lifting device in the driving state. 7. Device according to one of claims 3 to 6, characterized in that the supporting structures ( 7, 8, 9 ) are secured in the stacked unlocked state by supporting surfaces arranged on them ( 20 ) against an opposing displacement in at least one direction. 8. Device according to one of claims 3 to 7, characterized in that the support structures ( 8, 9 ) are provided with spring-loaded rollers ( 22 ), the springs being designed such that the support structures ( 8, 9 ) are individually unloaded are freely available.